JP3863603B2 - Acoustic signal processing device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an acoustic signal processing apparatus, and relates to an apparatus using a digital device such as a digital signal processing apparatus (DSP).
[0002]
[Prior art]
Some acoustic signal processing apparatuses use various devices such as an equalizer, a delay, and a channel divider. In the case where these devices perform analog signal processing, when the configuration of the acoustic signal device is changed, the above-described devices are added or removed. However, in this case, there is a high possibility that an error in wiring will occur when equipment is added or removed, and such work takes a lot of time.
[0003]
In order to solve this problem, there is one that digitally processes an acoustic signal using, for example, a DSP. That is, the functions of various devices as described above are achieved by writing a program in the DSP. When changing the functions of various devices, the DSP program is rewritten from, for example, another personal computer.
[0004]
[Problems to be solved by the invention]
However, if digital processing of the sound signal by the DSP is continued while rewriting the program of the DSP, it is unclear how the processed sound signal is output, and the listener is uncomfortable. There is a possibility to give. Therefore, while the DSP program is being rewritten, the DSP does not output a digitally processed acoustic signal. However, there has been a problem that so-called sound interruption occurs during rewriting of the DSP program.
[0005]
[Means for Solving the Problems]
In order to solve the above-mentioned problems, according to the first aspect of the present invention, a program for functioning as a plurality of digital signal processing means is downloaded when power is supplied, and the operation of each digital signal processing means is determined. A DSP that digitally processes a digital audio frequency signal input by each digital signal processing means based on data, and an addition that designates one of the digital signal processing means to be operated from those not currently operating A determination means for determining whether there is an instruction or a deletion instruction for designating what is to be stopped among those currently operating; and in the state where a digital audio frequency signal is input to the DSP, the additional instruction di when it is determined is to be operated newly by said determining means that there is Data for Tal signal processing means for digitally signal processing the digital audio frequency signal is supplied to the DSP, in a state where the digital audio frequency signal to the DSP is inputted by said determining means and said there is deletion instruction If it is determined, the digital signal processing means to be stopped comprises data supply means for supplying the DSP with data for passing the digital audio frequency signal.
[0006]
According to the first aspect of the present invention, the digital signal processing means only allows the inputted digital audio frequency signal to pass in the state where data for simply passing the digital audio frequency signal is supplied. . However, the digital signal processing means functions as an equalizer, a channel divider, a delay, etc. as described above , for example , in a state where data for signal processing by the digital signal processing means to be newly operated is supplied .
[0009]
According to a second aspect of the present invention, in the acoustic signal processing device according to the first aspect, the digital signal processing means are cascade-connected.
[0010]
According to the second aspect of the present invention , since the digital signal processing means are cascade-connected, data for simply passing the digital audio frequency signal is input to the supplied digital signal processing means. The digital audio frequency signal is supplied to the subsequent digital signal processing means. Therefore, even if a large number of digital signal processing means for achieving different functions are provided, signal processing is performed only by the desired digital signal processing means.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
In the first embodiment of the present invention, the acoustic signal processing device 2 has a digital signal processing device (DSP) 4 as shown in FIG. A digital audio frequency signal obtained by digitizing an analog audio frequency signal by the A / D converter 6 is supplied to the DSP 4.
[0018]
The acoustic signal processing device 2 is provided with a CPU 8 and a program ROM 10 in addition to the DSP 4. The program ROM 10 stores a program for causing the DSP 4 to function as a plurality of predetermined number of digital signal processing means 4a, 4b..., For example, a digital equalizer, a digital delay, a digital channel divider, and the like. These programs are read from the program ROM 10 by the CPU 8 and written to the DSP 4. That is, it is downloaded. This downloading is performed by the CPU 8 when the sound signal processing device 4 is powered on.
[0019]
In order for the DSP 4 to function as each digital signal processing means in a state where the program is downloaded to the DSP 4, characteristics data, for example, coefficients for various digital filters used in the digital equalizer, coefficients for determining the delay time in the digital delay, etc. Must be entered. When these data are not stored and through data is supplied, each digital signal processing means only passes the digital audio frequency signal input thereto.
[0020]
Further, as schematically shown in FIG. 1, the program is configured such that the digital signal processing means are in cascade connection. That is, when the DSP 4 is caused to function as, for example, five digital signal processing means 4a to 4e, a program in which the five digital signal processing means 4a to 4e are connected in cascade is downloaded to the DSP 4.
[0021]
The digital audio frequency signal processed in the DSP 4 is converted to an analog signal by the D / A converter 12 and supplied to, for example, a speaker system. In FIG. 1, for the sake of simplicity, the DSP 4 is shown to process a digital audible frequency signal of one channel, but the digital signals connected in cascade as described above for a plurality of channels. Each processing means can be provided.
[0022]
The characteristic data or the through data for each digital signal processing means as described above is generated by the personal computer 14 and given to the DSP 4 via the CPU 8. The characteristic data is not given to all the digital signal processing means, but is given to the digital signal processing means intended to function, and among the digital signal processing means that have been functioning so far, For those that simply stop the digital signal and pass the digital signal, through data is supplied instead of the data that has been given so far.
[0023]
Therefore, for example, the digital signal processing means 4a, 4b and 4e are functioned. However, when the function of the digital signal processing means 4a is stopped and the digital signal processing means 4d is newly functioned, the digital signal is sent from the personal computer 14. The characteristic data for the processing means 4d is supplied to the CPU 8, and an instruction to change the data for the digital signal processing means 4a to through data is supplied to the CPU 8 from the personal computer 14. As a result, the CPU 8 supplies the characteristic data and the through data to the DSP 4. The supply of the characteristic data and the through data can be performed in a very short time compared to downloading the program of the DSP 4. This is possible because all programs are downloaded to the DSP 4 when the power is turned on in advance.
[0024]
Since the DSP 4 is pre-programmed in a state where all the digital signal processing means that may be used are connected in cascade, the configuration of the acoustic signal processing device 2 can be configured simply by supplying characteristic data and through data. It can be changed in an instant. Moreover, since the supply of the characteristic data and the through data is performed instantaneously, even if the characteristic data and the through data are supplied while the DSP 4 is performing signal processing, there is no occurrence of sound interruption. Even if a strange sound is generated due to the change of the configuration, it is in a very short time, so that the listener will not notice it.
[0025]
FIG. 2 is a flowchart showing the operation performed by the CPU 8. First, when power is turned on to the acoustic signal processing device 2, the CPU 8 first downloads all programs from the program ROM 10 to the DSP 4 (step S2). Then, it is determined whether an instruction to add or delete a function is given to the DSP 4 from the personal computer 14 (step S4). That is, among the digital signal processing means achieved by the DSP 4, there is an instruction for designating what is to be operated among those which are not currently in operation, or an instruction for designating what is to be stopped among those currently in operation. Judge.
[0026]
If this instruction is not given, step S4 is repeated until this instruction is given. If there is this instruction, the CPU 8 determines whether the instruction is addition or deletion (step S6). In the case of addition, the CPU 8 sends data for the function to be added, that is, data for the digital signal processing means to be newly operated, to the DSP 4 (step S8). This data can be given from the personal computer 14, or the data previously written in the program ROM 10 may be read out from the program ROM 10 and written in the DSP 4.
[0027]
If it is determined in step S6 that the instruction is to delete, the CPU 8 sends data for the function to be deleted, that is, data for the digital signal processing means, that is, data for simply allowing the digital signal to pass through to the DSP 4. (Step S10). The function addition or deletion data can be created in the personal computer 14 and given to the DSP 4 via the CPU 8, or the data written in the program ROM 10 in advance by the CPU 8 can be stored in the personal computer 14. May be read from the program ROM 10 based on an instruction from the program and written to the DSP 4. When these steps S8 and S10 are completed, the process returns to step S4.
[0028]
In the first embodiment, the DSP 4 functions as a plurality of digital signal processing means. However, the DSP 4 only needs to function as at least one digital signal processing means.
[0029]
A second embodiment of the present invention is shown in FIG. In this embodiment, a DSP 40 is used. Since other configurations are the same as those of the first embodiment, detailed description thereof is omitted. The DSP 40 is configured to be capable of realizing at least two signal processing sequences for one input digital audio frequency signal. Each signal processing series includes a plurality of digital signal processing means. However, one signal processing sequence A and the other signal processing sequence B have different overall processing characteristics.
[0030]
For example, each digital signal processing means constituting one signal processing sequence A and each digital signal processing means constituting the other signal processing sequence B are the same number, but part or all of them. The signal processing performed by the digital signal processing means may be different. The total number of digital signal processing means constituting one signal processing sequence A is different from that of each digital signal processing means constituting the other signal processing sequence B, and some or all of them are different. The signal processing performed by the digital signal processing means may be different.
[0031]
For example, when it is necessary to switch to the digital signal processing in the other signal processing sequence B in the state in which the digital signal processing is performed in one signal processing sequence A, the CPU 8 is instructed by an instruction from the personal computer 14. Then, a program for causing the DSP 40 to configure the signal processing sequence B is read from the program ROM 10 and downloaded to the DSP 40. This program is naturally different from a program for causing the DSP 40 to configure the signal processing sequence A. The characteristic data necessary for each signal processing means of the signal processing sequence B to perform signal processing is also given to the DSP 40 when the program is downloaded. Of course, this characteristic data can be changed later.
[0032]
When the download is completed, the CPU 8 causes the switching means, for example, the crossfade unit 42, to which the outputs of the signal processing series A and the signal processing series B are supplied to the DSP 40, performs close fade processing. In this case, the output of the signal processing sequence A is gradually decreased, the output of the signal processing sequence is gradually increased, and finally the output of the signal processing sequence A is set to 0 and the output of the signal processing sequence B is maximized. Let
[0033]
In this embodiment, two signal processing sequences A and B can be realized by the DSP 40. While one of the signal processing sequences is performing signal processing, the other signal processing sequence is also realized by the DSP 40. After this realization, the signal processing sequence for outputting the signal-processed signal is switched from one signal processing sequence to the other signal processing sequence, so that unpleasant sound is not output and sound interruption does not occur. . In addition, since this switching is performed by crossfading, it is possible to make it difficult for the listener to recognize that the switching has been performed.
[0034]
In order to operate the DSP 40 in this way, the CPU 8 performs processing as shown in FIG. This process is started, for example, when a download instruction is given from the personal computer 14. First, the CPU 8 determines a signal processing sequence to be newly downloaded (step S12). That is, it is determined which signal processing series is newly given from the personal computer 14. If this sequence is, for example, the signal processing sequence A, the signal processing sequence A to be downloaded is stored as C, and the sequence B that is not downloaded is stored as CN (step S14). On the other hand, if the signal processing sequence to which a new configuration instruction is given is the signal processing sequence B, the signal processing sequence B to be downloaded is stored as C, and the sequence A that is not downloaded is stored as CN (step S16). .
[0035]
Then, following step S14 or S16, a program of the signal processing sequence C to be downloaded is downloaded (step S18). Then, it is determined whether the download has been completed (step S20). If it has not been completed, steps S18 and S20 are repeated until the download is completed.
[0036]
When the download is completed, the output from the downloaded signal processing sequence C is gradually increased, and the output from the originally existing signal processing sequence CN that has not been downloaded is gradually decreased (step S22). That is, a cross fade is executed.
[0037]
It should be noted that the original signal processing sequence program is deleted from the DSP 40 after the sequence for performing signal processing is switched in this way. This reduces the burden on the DSP 40 for signal processing.
[0038]
In this embodiment, only the DSP 40 is provided. However, a plurality of DSPs may be provided, and each DSP may constitute one signal processing sequence. In this case, the burden on the DSP is reduced.
[0039]
The program ROM 10 stores a plurality of programs for configuring a plurality of other signal processing sequences in addition to the programs for configuring the two signal processing sequences A and B described above. Any one of them may be downloaded to the DSP 40 when the signal processing sequence is switched.
[0040]
【The invention's effect】
As described above, according to the first aspect of the present invention, the digital signal processing means by the DSP is configured at the time of power supply , and in a state where data for simply passing the digital audio frequency signal is supplied, In the state where the digital signal processing means that passes the digital audible frequency signal and is newly operated is supplied with data for signal processing , processing corresponding to the characteristic data is performed. Moreover, the time required for supplying each data is very short. Therefore, the time required for the digital signal processing means to shift from the state of processing to the state of passing through the signal or vice versa is very short, so that the listener does not hear an unpleasant sound. No sound breaks out.
[0042]
According to the second aspect of the present invention , since each digital signal processing means is connected in cascade, it is supplied to the digital signal processing means supplied with data for simply passing the digital audio frequency signal. The digital audio frequency signal is supplied to the subsequent digital signal processing means. Therefore, even if a large number of digital signal processing means for achieving different functions are provided, signal processing is performed by the desired digital signal processing means. If a configuration is such that a part of each digital signal processing means is cascade-connected and the other digital signal processing means is connected in parallel to the cascaded digital signal processing means, for example, it is connected in parallel. When data for simply passing a digital audio frequency signal is supplied to the digital signal processing means, the signal that has passed through the digital signal processing means of this parallel shunt is also output, and the desired processing is performed. It is not possible to output a signal that has been made. However, if all the digital signal processing means are connected in cascade, such unnecessary signals are not output.
[Brief description of the drawings]
FIG. 1 is a block diagram of a first embodiment of an acoustic signal processing device according to the present invention.
FIG. 2 is a flowchart of the CPU according to the first embodiment;
FIG. 3 is a block diagram of the second embodiment;
FIG. 4 is a flowchart of the CPU according to the second embodiment;
[Explanation of symbols]
2 Acoustic signal processing device 4 40 DSP (acoustic signal processing unit, digital signal processing means)
8 CPU (data supply means)

Claims (2)

A digital audible frequency in which a program for functioning as a plurality of digital signal processing means is downloaded when power is supplied, and each digital signal processing means is input based on data that determines the operation of each digital signal processing means A DSP for digital signal processing of the signal ;
Judgment as to whether there is an addition instruction that designates one of the digital signal processing means that is not currently operated to be operated or a deletion instruction that designates one that is currently operated to stop the operation. A determination means for performing
In a state where a digital audio frequency signal is input to the DSP, if the determination means determines that there is the additional instruction , a digital signal processing means to newly operate the digital audio frequency signal. When data for digital signal processing is supplied to the DSP and a digital audible frequency signal is input to the DSP, if it is determined by the determination means that the deletion instruction is issued, the DSP attempts to stop the processing. Data supply means for supplying the DSP with data for allowing the digital signal processing means to pass the digital audio frequency signal;
An acoustic signal processing apparatus.   2. The acoustic signal processing apparatus according to claim 1, wherein the digital signal processing means are connected in cascade.

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